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SMES

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SMESNew.png Terminal.png Superconducting Magnetic Energy Storage (often shortened to SMES) is a device used to store electrical power. While SMES units are very effective, they are also expensive, requiring high end circuit board and expensive parts. If you need to quickly replace the SMES you may try using cheaper but less powerful Cell Rack PSU instead. SMES units may be upgraded to increase their capacity and/or maximal input/output levels.

Configuration

SMES units may be configured via interface which is opened by left-clicking with empty hand on the SMES. Alternatively you may use the RCON console to operate most SMESs on station. The interface looks like this:
SMES GUI.png

Input

Each SMES needs terminal to operate properly. This terminal allows you to charge the SMES from one power network, and output into another one. By using apropriate controls in the GUI you may set any input value up to certain cap. This cap can be increased by upgrading the SMES unit, as described further in this guide. Also, please note that setting larger input than available will cause the SMES to enter "Partially Charging" state. This means the SMES is still charging, but not at set input rate. You may choose from two input options - OFF and AUTO.

Output

The SMES outputs power into wire placed directly under it. Usually, you want to keep output lower than input, however sometimes you may have to increase output to compensate for larger demans. This is common with main Engine SMES when setting up Substations. The output rate is also capped and also upgradable. You may choose from two output options which are self explanatory - ONLINE and OFFLINE.

Values

These are example settings for few SMESs around the station. You may choose different settings, depending on available power and other factors. Try to consult the Chief Engineer when unsure. More information may also be found at following pages: Engine, Substations.

Location Input Output Other notes
Engine Room SMES 250 kW, Auto 250 kW, Online Generally, you want the Engine SMES to be charged to ensure cooling will remain operational. Refer to Engine for more information.
Main SMES 1000 kW, Auto 1000 kW, Online Unless engine is producing really low amount of energy, this should work well. If Engine Room SMES is running low, increase input on this one a bit.
Solar SMESs (Side) 250 kW, Auto 100 kW, Offline It is usually good idea to leave solar array SMESs in output offline mode, until they are needed. Input should always be above or equal to 180kW, otherwise some energy may be wasted.
Solar SMESs (Bridge) 1000 kW, Auto 250 kW, Offline Bridge solar array is much larger, and therefore has larger SMES installed.
Atmospherics SMES 250 kW, Auto 250 kW, Online Some things, espicially pumps, use large amounts of power. This means atmospherics needs a lot of power. Consider lowering output only when the power supply is highly limited.
AI Core SMES 125 kW, Auto 100 kW, Online The AI uses 50kW of energy, which leaves 50kW for turrets, lights, etc. Remember to increase if you have more than one AI in AI Core room.
Substation SMESs 250 kW, Auto 200 kW, Online Refer to page Substations for more information.

Deconstruction

Required tools

  • Screwdriver4.png Screwdriver
  • Crowbar.png Crowbar
  • Wirecutters.png Wirecutters
  • Welderon 32px.gif Welding Tool
  • Wrench.png Wrench
  • Yellowgloves.png Insultated Gloves (optional, but reccomended)
  • Multitool.png Multitool (optional, only if you decide to disable failsafes)

Preparations

  1. First of all you should ensure the SMES is discharged. While there is a workaround, it may (read: will) cause an injury and/or damage.
  2. Open the SMES's interface by left clicking it. Ensure both Input and Output are turned Off.
  3. Use screwdriver on the SMES to open the access panel.
  4. Use wirecutters on the SMES to cut the terminal. If the terminal is missing (or destroyed) simply skip this step.

Deconstruction Steps

  1. Complete everything in Preparations
  2. (OPTIONAL) Use multitool on the SMES to disconnect safety circuit. This step may be skipped if you completely discharged the SMES. DO NOT PROCEED IF SMES IS CHARGED ABOVE 50%, usually, anything below 15% is safe(with gloves). Anything above 50% is likely to kill you.
  3. Use crowbar on the SMES to begin removing the components. This may take up to 60 seconds, depending on amount of coils in the SMES. Basic SMESs should take approximately 10 seconds. SMES will turn into machine frame and few components. You may use these components for research or for repairs/upgrades.
  4. Use wirecutters to remove cables from the machine frame
  5. Use wrench to dismantle the machine frame

SMES Failure

Disabling failsafes, as outlined in Hacking section of this page may cause SMES Failure when removing the components (crowbar step), or adding new components (inserting new coils). Chance of "something bad" happening is directly proportional to SMES charge percentage. SMES charged to 75% has 75% probability of failing, etc. If this failure happens, effects are once again related to charge percentage.

  • Discharge - (Always) The SMES will lose ALL it's remaining charge.
  • Sparks - (Always) Mostly harmless, some sparks will fly from the SMES, potentionally igniting fire if flammable material is nearby.
  • Electrocution - (Always) Shocks the user. Please note that while insultated gloves mitigate the effect, they aren't guaranteed to 100% protect you. Damage scales with charge percentage. Anything above 60% charge is instant-kill even with gloves.
  • EM Pulse - (above 15% charge) Causes electromagnetic pulse which breaks nearby electronics. This usually trips fire alarms, breaks consoles, and may even kill/injure the AI/cyborgs/people with prosthetics depending on situation. Size of EM Pulse is proportional to amount of stored power.
  • APC Overload - (above 35% charge) Overloads lighting circuits of few APCs connected to the SMES's output. Please note that having something between the SMES and APC (such as, another SMES) will prevent the damage. Chance is proportional to amount of stored power.
  • APC Failure - (above 35% charge) Completely breaks few APCs in SMES's output. Same rule as above applies.
  • Magnetic Containment Failure - (above 60% charge) The worst thing that can happen. If SMES's magnetic containment fails remaining charge is released in form of violent explosion. The SMES is completely destroyed, as well as few nearby tiles. This almost always causes hull breach, and the explosion may gib you. After this failure is triggered you have 30-60 seconds before the SMES blows up.

Hacking

SMES units may be hacked to enable or disable various features. Remember to wear your Yellowgloves.png protective equipment or risk injury. To access the wiring open front panel with screwdriver. Then click the SMES with empty hand to open up wiring window. There are five wires, which have randomized colours every round.

  • Input - Cutting this will cause the SMES to stop inputting. Pulsing will temporarily disable input.
  • Output - Cutting this will cause the SMES to stop outputting. Pulsing will temporarily disable output.
  • RCON - Cutting this will disable RCON (Remote CONtrol), hiding the SMES from control consoles. It also disables AI control. Pulsing does nothing.
  • Failsafes - Cutting will allow you to modify the SMES even if it is charged. Please note that this may result in catastrophic overload if charge is large enough. Pulsing does nothing.
  • Grounding - Cutting or pulsing this wire will overload the SMES, causing quick dissipation of stored energy. This energy may however damage or destroy APCs in output power network, so it is advised to either disconnect the SMES, or at least use Substations to prevent damage to many APCs. Mending will restore grounding and stop the overload. This is highly similar failure of charged SMES, but with less risks involved for the user. Remember that doing this as non-antagonist is not a good idea.

Construction

Required Tools

  • CableCoils.png Cable Coil, 2x (two full coils)
  • Metal.png Metal Sheets, 5x
  • Circuitboard.png SMES Circuit Board - May be obtained from Research, or salvaged from existing SMESs
  • SMESCoil.png Superconducting Magnetic Coil - May be obtained from Cargo or salvaged from existing SMES. You need at least one coil, but adding more coils increases capacity and input/output cap of the SMES. You may add up to six coils into single SMES.
  • Yellowgloves.png Insultated Gloves - Optional, but reccomended (espicially if you are going to manipulate wiring)

Construction Steps

  1. Use your metal sheets to build machine frame.
  2. Use your cable coil on machine frame to add wires.
  3. (OPTIONAL) place wire under the machine frame. The SMES will output into this wire.
  4. Use your SMES Circuit Board on wired machine frame.
  5. Add 30 pieces of cable (one full length cable coil).
  6. Add one superconducting magnetic coil.
  7. Finalise the SMES with screwdriver.

Terminal

New SMES starts without terminal. Furthermore, terminals may be damaged by explosions or similar effects. Fortunately, installing new terminal is easy.

  1. Open interface of your SMES and turn it's input and output OFF.
  2. Use screwdriver on the SMES to open the cover.
  3. Use cable coil on the SMES to add new terminal. You need 10 pieces of cable for this. If you make a mistake use wirecutters to remove the terminal and repeat this step.
  4. Use screwdriver on the SMES to close the cover.

RCON Settings

RCON, or Remote CONtrol, allows remote operation of SMESs from RCON console. To allow usage of RCON you have to set RCON tag. This tag has to be unique (ie. do not use tag already used by another SMES). To set new tag click the SMES with multitool. If you wish to disable RCON you may either cut apropriate wire (see Hacking section), or use tag "NO_TAG".

Upgrading

There are four types of coils in existence:

Name Capacity Throughput
Superconductive Magnetic Coils 50kWh 250kW
Superconductive Capacitance Coils 250kWh 100kW
Superconductive Transmission Coils 20kWh 1250kW
Basic Superconductive Magnetic Coils 10kWh 150kW

Two of each type of Magnetic, Transmission, and Capacitance are in each Engineering Hard Storage (Decks 1 and 3), in one of the crates.

Three SMES layouts are commonly used:

  1. 6x Regular coil: Very easy to set up as all it involves is tossing two extra regular coils into the main SMES. The SMES doesn't have to be dismantled for this, and therefore it's faster than other layouts. Somewhat increases capacity and transfer rate, but only to a limited degree.
  2. 2x Capacitance coil, 4x Transmission coil: This guide's author favorite. This setup results is very useful when combined with a ship-wide shield generator, as it has good storage capacity, while also allowing very rapid charging/discharging (which is ideal for shields). It's disadvantage is that you have to dismantle the main SMES completely, and rebuild it from scratch, using transmission/capacitance coils. When using this setup it's highly recommended to also use Substations as the wattage in main grid will be very dangerous.
  3. 2x Transmission coil, 4x Capacitance coil: An alternative to above setup. Sacrifices large portion of transfer rate for much larger capacity. A fully charged SMES with this setup can run the whole ship for few hours.


When building an SMES you may add only a single Magnetic Coil into it. However, you may add up to five more coils later. This process is slightly more complex than terminal replacement.

  1. Ensure the SMES is discharged. Alternatively, you may disable the failsafes (see point 4.). Please read the "SMES Failure" section of this guide before proceeding.
  2. Open interface of your SMES and turn it's input and output OFF.
  3. Use screwdriver on the SMES to open the cover.
  4. (OPTIONAL) Disable failsafes by cutting the correct wire (see Hacking section).
  5. Use your superconducting magnetic coil(s) on the SMES to install them.
  6. (OPTIONAL) Re-enable failsafes if you disabled them.
  7. Use screwdriver on the SMES to close the cover.